KR101126022B1 - Apparatus for eliminating white-smoke - Google Patents

Abstract

Disclosed is a white smoke removal apparatus capable of reducing white smoke generated when discharging a fluid containing steam, and recycling condensed water collected by phase conversion from water vapor.

The apparatus for removing white smoke includes a supply unit for supplying a fluid containing water vapor, and an injection unit connected to the supply part and injecting water for phase-converting and condensing water vapor contained in the inflowing fluid, and the And a heat exchange unit connected to the apparatus main body and supplying the outside air to the apparatus main body to be mixed with the fluid discharged from the apparatus main body after heat exchange between the condensed water condensed inside the apparatus main body and the suctioned outside air.

According to the white smoke removal device, the white smoke phenomenon can be reduced by heat-exchanging the condensed water condensed from the water vapor contained in the fluid and the outside air through the heat exchange unit, and then mixing the heat-exchanged outside air with the fluid discharged from the apparatus body. The condensed water cooled in the unit can be resupplied to the injection unit.

White lead, condensate, heat exchange

Description

White smoke removal device {APPARATUS FOR ELIMINATING WHITE-SMOKE}

The present invention relates to a white smoke removal apparatus, and more particularly, to a white smoke removal apparatus for removing a phenomenon in which water vapor that is exhausted by recovering moisture contained in a large amount of water vapor looks like white smoke.

In general, in the continuous casting process of steel mills, intermediate materials or facilities are cooled by a direct cooling device. That is, in the direct cooling apparatus, water is used as cooling water to cool intermediate materials such as slabs, blooms, billets, and the like, and equipment for producing such intermediate materials.

However, when water is used as cooling water to cool, water vapor is generally generated, and such water vapor is discharged to the outside so as not to interfere with operation.

As such, the water vapor discharged to the outside through the chimney contains a large amount of water, and when discharged into the chimney, a phenomenon that looks like white smoke (white smoke) occurs. This white smoke is formed when the heated wet air is cooled below the dew point in the process of dilution with cold air of the atmosphere. The white smoke occurs in an environment where the upper side of the humid air curve is cooled to 100% of the saturation curve.

In particular, white smoke occurs when warm discharge air mixes with cold air.

In other words, the water vapor discharged from the direct cooling device suddenly drops in temperature as it is mixed with external air (outside air) when discharged into hot and humid air. At this time, since humidity cannot theoretically exist at more than 100%, supersaturated water vapor is made into water droplets with temperature drop, and white water phenomena that look like white smoke are generated.

Although white smoke is not a pollutant, it also looks like a visible pollution that is visually burdened when viewed from the outside.Also, excessive water droplets form around the chimney, causing discomfort or falling on the road and freezing in winter. There is a problem.

In addition, the cooling water is converted into water vapor through the phase change is discharged to the outside there is a problem that the cooling water converted to water vapor is consumed. That is, because the cooling water must be replenished according to the evaporation consumption of the cooling water, there is a problem that the cooling water replenishment cost increases.

An object of the present invention is to provide a white smoke removal apparatus that can reduce the white smoke phenomenon generated during the discharge of a fluid containing water vapor.

In addition, an object of the present invention is to provide a white smoke removal device that can recycle the condensed water collected by phase conversion from water vapor.

The apparatus for removing white smoke according to the present invention includes a supply unit for supplying a fluid containing water vapor, and an injection unit connected to the supply part and injecting water to inject water to condense by converting water vapor contained in the inflowing fluid; And a heat exchange unit connected to the apparatus main body and supplying the outside air to the apparatus main body to be mixed with the fluid discharged from the apparatus main body after heat exchange between the condensed water condensed inside the apparatus main body and the suctioned outside air.

The apparatus for removing white smoke is provided at a lower end of the apparatus main body and further includes a storage unit connected to the heat exchange unit such that condensed water condensed by phase conversion of water vapor contained in the fluid is stored and supplied to the heat exchange unit.

The heat exchange unit includes a heat exchanger for heat-exchanging sucked outside air with condensate supplied from the apparatus main body, an external air inlet fan connected to the heat exchanger for introducing outside air, and external air heat-exchanged with condensate water to the fluid discharged from the apparatus main body. It may be provided with a connecting pipe for connecting the heat exchanger and the device body so as to supply.

The heat exchange unit may further include a supplemental water supply pipe connected to the injection unit to supply the condensed water that has exchanged heat with the outside air to the injection unit.

The injection unit is provided with a first supply unit for supplying water injected into the fluid and a first injection unit having a plurality of first injection nozzles installed in the first supply pipe for injecting water into the fluid, and the water injected into the fluid It is provided with a second supply pipe and the second supply pipe is provided with a plurality of second injection nozzles for injecting water into the fluid and may be provided with a second injection unit spaced apart from the rear end of the first injection unit on the flow path of the fluid have.

The white smoke removal device may further include a dispersion member provided in the body main body to be disposed at the front end of the injection unit on the flow path of the fluid.

The dispersing member is provided on an upper portion of the duct member to disperse a fluid flowing therein, and a fluid disposed on the upper portion of the first dispersing member and passed through the first dispensing unit provided in the dispensing unit is dispersed. It may be provided with a second dispersion member for dispersing the fluid to flow.

The apparatus body may include a droplet growth unit disposed at a rear end of the injection unit on a flow path of the fluid and growing droplets generated from water vapor contained in the fluid.

The white smoke removal device may be provided in the apparatus body so as to be disposed between the first and second injection units, and may further include an external air supply unit supplying external air to condense water vapor contained in the fluid.

The outside air supply unit may include a blowing fan that sucks outside air and flows into the inside of the apparatus main body, and an outside air supply pipe connecting the blowing fan and the apparatus main body.

The apparatus for removing white smoke may further include an adsorption unit provided at an upper end of the apparatus main body to adsorb water vapor contained in the discharged fluid.

The adsorption unit includes a first adsorption member for adsorbing the droplets grown and contained in the fluid, and a second adsorption member for adsorbing the droplets remaining in the fluid at a rear end of the first adsorption member on the flow path of the flowing fluid. It can be provided.

The supply unit may include a flow path tube through which water vapor flows, and a suction fan connected to the flow path pipe to introduce water vapor into the apparatus body.

According to the present invention, there is an effect that the white smoke phenomenon can be reduced by allowing the heat exchanged condensed water and the outside air to be exchanged with the fluid discharged from the apparatus main body after heat-exchanging condensed water from the water vapor contained in the fluid.

In addition, since the condensate can be cooled by heat-exchanging the condensate condensed in the outside air and the device body through the heat exchange unit, the condensate having a lower temperature can be supplied to the injection unit.

In addition, by increasing the size of the droplets generated from the water vapor contained in the fluid through a plurality of injection units there is an effect that can increase the amount of condensed water collected from the water vapor.

In addition, according to the present invention, by reducing the deflection flow of the water vapor flowing through the plurality of dispersion members so that the water vapor can be dispersed and flow, while reducing the flow rate of water vapor, the condensed water collected from the water vapor There is an effect that can increase the amount.

In addition, according to the present invention, there is an effect that the amount of condensed water collected from the water vapor can be increased by sufficiently providing the time required for the droplets generated from the water vapor contained in the fluid to grow through the liquid drop growth unit.

Hereinafter, with reference to the drawings, it will be described in the smoke removal apparatus according to an embodiment of the present invention.

1 is a block diagram showing a white smoke removal apparatus according to an embodiment of the present invention, Figure 2 is a block diagram showing the internal configuration of the apparatus main body provided in the white smoke removal apparatus according to an embodiment of the present invention.

1 and 2, as an example, the apparatus 100 for removing white smoke may include, for example, a supply unit 110, an apparatus body 120, an injection unit 130, a dispersion member 160, and a droplet growth unit 170. The unit 180, an external air supply unit 190, a storage unit 200, and a heat exchange unit 210 are included.

The supply unit 110 supplies a fluid containing water vapor. That is, as an example, the fluid containing water vapor discharged from the reproducing process of the steel mill is introduced into the apparatus main body 120 through the supply unit 110. To this end, the supply unit 110 may include a flow path pipe 112 through which water vapor flows into the inside, and a suction fan 114 connected to the flow path pipe 112 to introduce water vapor into the apparatus body 120.

As an example, the flow path tube 112 may be connected to a chimney 10 provided with a fluid containing water vapor to be discharged to the outside, and the fluid containing water vapor discharged through the chimney 10 may be a suction fan 114. By flow into the flow pipe 112 is supplied to the interior of the device body 120.

On the other hand, in the present embodiment has been described a case in which the flow pipe 112 is connected to the chimney 10 as an example, but is not limited to this, the flow pipe 112 may be connected to the steam collecting device provided in the playing process. .

The apparatus main body 120 includes an injection unit 130 for injecting water in order to phase change and condense water vapor contained in the fluid supplied from the supply unit 110.

On the other hand, the device body 120 serves to provide a flow path through which the fluid containing water vapor flows, for this purpose the device body 120 may be formed in the shape of a duct pipe having a hollow box shape or a cylindrical shape. have.

In addition, the upper side of the apparatus main body 120 may be provided with an opening (not shown) to discharge the fluid recovered the steam. That is, the fluid from which some steam is removed from the fluid containing steam is discharged from the apparatus main body 120 through the opening part.

On the other hand, the device body 120 may be provided with an opening and closing member 122 that is opened during maintenance, repair of the inside. That is, one side of the device body 120 is provided with an opening member 122 for providing a passage for the operator to enter and exit the device body 120, the injection unit 130, the adsorption unit (installed therein) 180) such as maintenance and repair is possible.

The injection unit 130 may be provided in the apparatus main body 120 to inject water into the fluid introduced therein, and may be configured to be spaced apart from each other.

As an example, the injection unit 130 may include a first injection unit 140 and a second injection unit 150, and the fluid passing through the first and second injection units 140 and 150 may include a first and a second injection unit ( Water is sprayed through 140,150.

The first injection unit 140 includes a first supply pipe 142 for supplying water injected into the fluid and a plurality of first injection nozzles 144 installed in the first supply pipe 142 to spray water.

The first supply pipe 142 may be arranged to form a plurality of rows in the interior of the apparatus body 120, the water supplied to the first supply pipe 142, each of the first supply pipe 142 is arranged to form a plurality of rows It is injected through a plurality of first injection nozzles 144 installed in.

Accordingly, the fluid passing through the first injection unit 140 is in contact with water so that the droplets of water vapor contained in the fluid grow in size due to the condensation effect and the gas-liquid contact.

The second injection unit 150 is spaced apart from the rear end of the first injection unit 140 on the flow path of the fluid. That is, the second injection unit 150 is installed on the apparatus main body 120 so as to be disposed on the first injection unit 140 to inject water to the fluid flowing.

To this end, the second injection unit 150 is also installed in the second supply pipe 152 and the second supply pipe 152 to which water to be sprayed is supplied, and a plurality of second injection nozzles 154 to inject water into the fluid. Equipped.

That is, the second supply pipe 152 may also be arranged to form a plurality of rows inside the apparatus body 120, and the water supplied to the second supply pipe 152 may be configured to form a plurality of rows of second supply pipes 152. ) Are sprayed through a plurality of second spray nozzles 154 installed in the nozzles.

Accordingly, the fluid passing through the second injection unit 150 is in contact with water so that the droplet of the water vapor contained in the fluid is further increased in size by the condensation effect and gas-liquid contact.

For example, droplets of water vapor contained in the fluid are grown to 100 µm or more, and recovery by gravity and recovery by the adsorption unit 180 are facilitated.

As a result, the recovery efficiency of water vapor from the fluid is improved.

The dispersion member 160 is provided in the apparatus body 120 to be disposed at the front end of the injection unit 130 on the flow path of the fluid. That is, the dispersion member 160 is installed in the apparatus body 120 to be disposed below each of the first and second injection units 140 and 150, and distributes the fluid flowing therein. In addition, the dispersion member 160 may include, for example, a first dispersion member 162 and a second dispersion member 164.

The first dispersion member 162 is installed in the apparatus main body 120 to be disposed below the first injection unit 140, and flowed into the apparatus main body 120 by the supply unit 110 and stored in the storage unit 200. The fluid primarily dispersed by the condensate causes the flow to flow more evenly upwards.

In addition, the first dispersion member 162 may be formed to have a plate shape, and has a plurality of through holes 162a to distribute the fluid flowing therethrough.

On the other hand, the second dispersion member 164 is installed in the apparatus body 120 to be disposed between the first injection unit 140 and the second injection unit 150, the fluid passing through the first injection unit 140 Is dispersed to distribute the fluid so as to pass through the second injection unit 150.

In addition, the second dispersion member 164 may also be formed to have a plate shape, and has a plurality of through holes 164a to disperse the flowing fluid.

As such, the fluid flowing by the dispersion member 160 may be dispersed and flowed. That is, the fluid introduced into the apparatus body 120 through the supply unit 110 is primarily dispersed by the condensed water stored in the storage unit 200 to flow to the upper side, and then the first and second dispersion members 162 and 164. Can be dispersed through and flow to the upper side.

In other words, the deflection flow of the fluid flowing by the dispersion member 160 may be further reduced to have a uniform air flow distribution, thereby increasing the condensed water condensed from the water vapor.

The droplet growth unit 170 is disposed at the rear end of the injection unit 130 on the flow path of the fluid, and grows droplets generated from the water vapor contained in the fluid. That is, the droplet growth unit 170 is provided in the apparatus main body 120 to be disposed between the second injection unit 150 and the adsorption unit 180, the water vapor contained in the fluid first, second injection unit (140, 150) The reaction time can be ensured that the droplets grow in response to the water sprayed from.

That is, droplets of water vapor contained in the fluid are grown while passing through the droplet growth unit 170. In addition, the flowing fluid becomes more uniform in the flow distribution while passing through the liquid crystal growth unit 170, and thus the amount of condensed water recovered from the adsorption unit 180 may be further increased.

On the other hand, the adsorption unit 180 is provided on the upper end of the device body 120, and adsorbs the water vapor contained in the discharged fluid. To this end, the adsorption unit 180 is disposed at the rear end of the first adsorption member 182 on the flow path of the fluid and the first adsorption member 182 that adsorbs the grown liquid contained in the fluid and remains in the fluid. The second adsorption member 184 may be provided to adsorb the droplets.

The first adsorption member 182 may be formed of a porous filter to allow the fluid to flow therethrough, and may be provided in the apparatus body 120 to be disposed above the droplet growth unit 170. On the other hand, the first adsorption member 182 may be inclined in a zigzag to increase the contact area with the flowing fluid.

As such, droplets contained in the fluid passing through the first adsorption member 182 made of a porous filter may be adsorbed by the first adsorption member 182 and removed from the fluid.

The second adsorption member 184 is provided on the apparatus body 120 to be disposed above the first adsorption member 182, and may be made of a porous filter that is more finer than the first adsorption member 182. That is, droplets not removed from the first adsorption member 182 may be removed from the fluid flowing by the second adsorption member 184.

As described above, the fluid discharged from the apparatus main body 120 may be discharged while the water vapor contained therein is reduced while passing through the first and second adsorption members 182 and 184.

On the other hand, the white smoke removal device 100 is provided in the device body 120 to be disposed between the plurality of injection unit 130, and includes an air supply unit 190 for supplying the outside air to condense the water vapor contained in the fluid can do.

The outside air supply unit 190 may include a blowing fan 192 that sucks outside air and flows into the inside of the apparatus body 120, and an outside air supply pipe 194 connecting the blowing fan 192 and the apparatus body 120. Can be.

Looking in more detail, the outside air supply unit 190 may be provided in the apparatus body 120 to be disposed between the first injection unit 140 and the second injection unit 150. In addition, the outside air supply unit 190 includes a blower fan 192 and an outside air supply pipe 194 to supply the outside air to the inside of the apparatus main body 120.

That is, outside air is supplied to the fluid that has passed through the first injection unit 140 by the outside air supply unit 190, and the liquid containing the outside air and water vapor contacts to grow droplets of the water vapor.

In other words, by supplying outside air to the fluid containing water vapor, the temperature of the fluid is lowered and thus the dew point temperature of the fluid is lowered. Eventually, the amount of water condensed from the water vapor contained in the fluid is increased, so that the droplets can grow.

As such, since the droplets of the water vapor contained in the fluid may be increased by the external air supply unit 190, the amount of condensed water condensed from the water vapor may be further increased.

On the other hand, the storage unit 200 is provided at the lower end of the device body 120 serves to store the condensed water condensed. That is, the droplets condensed from the water vapor contained in the fluid is lowered by its own weight, in addition, the condensed water adsorbed by the adsorption unit 180 flows along the inner surface of the device body 120 to be introduced into the storage unit 200. Can be.

As such, the condensed water introduced into the storage 200 may be transferred for reuse.

The heat exchange unit 210 is connected to the apparatus main body 120, and the apparatus main body so as to be mixed with the fluid discharged from the apparatus main body 120 after the heat exchange between the condensed water condensed in the apparatus main body 120 and the sucked outside air 120).

To this end, the heat exchange unit 210 may include, for example, a heat exchanger 212, an outside air inlet fan 214, a connection pipe 216, and a supplemental water supply pipe 218.

The heat exchanger 212 exchanges the sucked outside air with the condensed water supplied from the apparatus main body 120. In more detail, the heat exchanger 212 may include a heat exchange pipe 212a through which condensed water is supplied from the storage unit 200 provided in the apparatus main body 120.

Meanwhile, the condensed water stored in the storage unit 200 is introduced into the heat exchange pipe 212a of the heat exchanger 212 through the condensate tube 220 connecting the heat exchanger 212 and the storage unit 200. In addition, a pump 222 is installed in the condensate pipe 220 to allow the condensed water stored in the storage 200 to flow into the heat exchange pipe 212a of the heat exchanger 212.

In addition, the heat exchange pipe 212a may be provided with a cooling fin (not shown) on the outer surface to improve the heat transfer efficiency.

Then, the outside air is introduced into the heat exchanger 212 by the outside air inlet fan 214 to exchange heat with the condensed water flowing along the heat exchange pipe 212a.

As a result, the temperature of the outside air passing through the heat exchanger 212 is raised, and the temperature of the condensed water is decreased.

The outside air inlet fan 214 allows the outside air to flow into the heat exchanger 212 and at the same time, the high temperature outside air whose temperature is raised by the heat exchange in the heat exchanger 212 can be introduced into the outlet of the device body 120.

The connection pipe 216 connects the heat exchanger 212 and the device body 120 to supply the fluid discharged from the device body 120 to heat the condensed water. That is, outside air whose temperature is raised by heat exchange with condensate is supplied to the upper side of the apparatus main body 120 through the connecting pipe 216.

Accordingly, the fluid in the hot and humid state discharged from the apparatus main body 120 becomes a fluid in the relatively hot and humid state while being mixed with the outside air whose temperature is raised. Thereafter, the fluid discharged from the apparatus main body 120 and the fluid having a high temperature and low humidity by mixing with the outside air whose temperature is raised are discharged from the apparatus main body 120, and the fluid in such a state may reduce the white smoke phenomenon even if it contacts the outdoor air. Can be.

Looking at this in more detail, the fluid discharged from the device body 120 is discharged after condensing a considerable amount of water vapor contained in the device body 120, it can be seen that the relatively high temperature and humidity compared to the outside air. When such a fluid is discharged and comes into contact with external air having a relatively low temperature, the fluid may change phase while passing through the white smoke generating section on the wet air line.

However, when the air heated in the heat exchanger 212 and the fluid discharged from the apparatus main body 120 are mixed, the mixed fluid is relatively hot and humid compared to the fluid discharged without mixing.

The white smoke generation rate generated by the fluid in the relatively high temperature and low humidity state is relatively low compared to the white smoke generation rate generated by the fluid discharged directly from the apparatus main body 120.

That is, since the outside air heated in the heat exchanger 212 is supplied to the upper side of the device body 120, the occurrence of the white smoke phenomenon can be further reduced.

On the other hand, the replenishment water supply pipe 218 is connected to the injection unit 130 so that the condensed water exchanged with the outside air is supplied to the injection unit 130 again. That is, the supplemental water supply pipe 218 has one side connected to the heat exchange pipe 212a of the heat exchanger 212, and the other side of the first and second injection units 140 and 150 provided in the injection unit 130. 2 is connected to the supply pipe (142,152).

That is, the condensed water supplied from the storage unit 200 to the heat exchanger 212 by the pump 222 is lowered through heat exchange to the first and second injection units 140 and 150 through the supplemental water supply pipe 218. Can be resupplied.

In addition, although not shown in the drawings, the replenishment water supply pipe 218 may be connected to a pipe for supplying condensed water in a playing process. That is, the condensed water having a lower temperature through heat exchange in the heat exchanger 212 may be transferred to the playing process and supplied to the playing process to be used as cooling water.

As described above, the white smoke phenomenon can be reduced by heat-exchanging the condensed water and the outside air condensed from the water vapor contained in the fluid through the heat exchange unit 210 and mixed with the fluid discharged from the apparatus main body 120. have.

In addition, since the condensate can be cooled by heat-exchanging the condensate condensed in the outside air and the apparatus main body 120 through the heat exchange unit 210, the condensed water having a lower temperature can be supplied to the injection unit 130.

Accordingly, the condensate can be recycled.

As the size of the droplets generated from the water vapor contained in the fluid is increased through the plurality of injection units 130, the amount of condensed water collected from the water vapor may be increased.

In addition, by reducing the deflection flow of water vapor flowing through the plurality of dispersion members 160 to allow the water vapor to be dispersed and flow, the flow rate of the water vapor can be reduced, thereby increasing the amount of condensed water collected from the water vapor. You can.

In addition, the droplet growth unit 170 provides the time required for growth of the droplets generated from the water vapor contained in the fluid and at the same time uniforms the flow distribution of the fluid, thereby reducing the amount of condensed water collected from the water vapor contained in the fluid. You can increase it.

Hereinafter, with reference to the drawings will be described the operation of the smoke removal apparatus according to an embodiment of the present invention.

3 is an operation diagram for explaining the operation of the smoke removal apparatus according to an embodiment of the present invention.

Referring to FIG. 3, first, a fluid containing water vapor is introduced into the apparatus main body 120 by the supply unit 110.

The introduced fluid passes through the first dispersion member 162, and thus the fluid flowing by being deflected by the speed of the introduced fluid has a uniform flow distribution. That is, the introduced fluid is dispersed and flows through the inside of the apparatus main body 120 with a uniform flow distribution.

As such, water is injected from the first injection unit 140 to the fluid passing through the first dispersion member 162. Accordingly, water vapor and water contained in the fluid come into contact with each other, and the droplet size is increased by the condensation effect and the gas-liquid contact.

Thereafter, the outside air is supplied to the fluid of which the droplet size is increased by the outside air supply unit 190. In contact with the outside air and the fluid, the dew point temperature of the fluid decreases, increasing the droplets condensing from the fluid and at the same time increasing the size of the droplets.

Thereafter, the fluid passes through the second dispersion member 164, whereby the flow distribution of the fluid becomes more uniform. As such, water is injected through the second injection unit 150 to the fluid flowing to have a uniform flow distribution. When the water injected by the second injection unit 150 and water vapor contained in the fluid contact, the size of the droplet is further increased.

On the other hand, the fluid in contact with the water by the second injection unit 150 then passes through the droplet growth unit 170, and thus the flow distribution of the fluid is more uniform, in addition to the flow of fluid for the growth of droplets Sufficient time is provided.

That is, the droplets of the fluid passing through the droplet growth unit 170 is increased in size while the fluid flows to have a uniform flow distribution.

Thereafter, the fluid passes through the adsorption unit 180, thereby recovering the condensed water from the water vapor contained in the fluid. That is, the grown droplets are removed from the fluid while passing through the first and second adsorption members 182 and 184.

As such, the fluid in which the amount of water vapor is reduced is discharged from the apparatus main body 120, and the fluid discharged from the apparatus main body 120 may reduce the white smoke effect generated during the discharge because the amount of water vapor is reduced.

In addition, the condensed water condensed from the apparatus main body 120 is recovered and stored in the storage unit 200 provided under the apparatus main body 120 by its own weight.

On the other hand, the condensed water recovered and stored in the storage unit 200 may be reused by the heat exchange unit 210. Looking at this, first stored in the storage unit 200 by the pump 222 installed in the condensate tube 220 Condensed water is supplied to the heat exchanger (212).

The condensed water flowing into the heat exchanger 212 flows along the heat exchange pipe 212a, and outside air is introduced into the heat exchanger 212 by the outside air inlet fan 214 of the heat exchange unit 210.

Accordingly, heat exchange is performed between the condensed water flowing along the heat exchange pipe 212a and the outside air introduced by the outside air inlet fan 214. Therefore, the temperature of condensate drops, and the temperature of outside air rises.

After that, the outside air whose temperature is increased by heat exchange flows along the connection pipe 216 and is mixed with the fluid discharged from the apparatus main body 120. Accordingly, the fluid in the hot and humid state discharged from the apparatus main body 120 becomes a fluid in the relatively hot and humid state while being mixed with the outdoor air whose temperature is raised.

Therefore, the mixed and relatively high temperature and low humidity fluid is discharged from the device body 120 can reduce the occurrence of white smoke phenomenon.

Meanwhile, the condensed water supplied from the storage unit 200 to the heat exchanger 212 and having the temperature lowered may be resupplied to the injection unit 130 through the supplemental water supply pipe 218. That is, the condensed water having a lower temperature through heat exchange with the outside air is supplied to the first and second supply pipes 142 and 152 of the first and second injection units 140 and 150 to be injected.

That is, the condensed water stored in the storage unit 200 is lowered in temperature through the heat exchanger 212, and condensed water having the lowered temperature is sprayed through the injection unit 130 and reused.

On the other hand, although not shown in the drawings, the supplemental water supply pipe 218 may be connected to the pipe for supplying condensed water in the playing process. That is, condensed water having a lower temperature through heat exchange in the heat exchanger 212 may be supplied to a regeneration process to be used as cooling water again.

As such, the condensed water stored in the storage unit 200 may be reused in the injection unit 130 or the playing process, thereby reducing the cooling water refilling cost.

As mentioned above

As the size of droplets generated from the water vapor contained in the fluid is increased through the plurality of injection units 130, the amount of condensed water collected from the water vapor may be increased.

In addition, by reducing the deflection flow of water vapor flowing through the plurality of dispersion members 160 to allow the water vapor to be dispersed and flow, the flow rate of the water vapor can be reduced, thereby increasing the amount of condensed water collected from the water vapor. You can.

In addition, through the droplet growth unit 170, the amount of condensed water collected from the water vapor can be increased by providing a sufficient time required for growth of the droplets generated from the water vapor contained in the fluid to grow and uniformizing the flow distribution of the fluid. .

By heat-exchanging condensed water and outside air condensed from water vapor contained in the fluid through the heat exchange unit 210, the heat exchanged outside air may be mixed with the fluid discharged from the apparatus main body 120, thereby reducing white smoke.

In addition, since the condensate can be cooled by heat-exchanging the condensate condensed in the outside air and the apparatus main body 120 through the heat exchange unit 210, the condensed water having a lower temperature can be supplied to the injection unit 130.

Accordingly, the condensate can be recycled.

As the size of the droplets generated from the water vapor contained in the fluid is increased through the plurality of injection units 130, the amount of condensed water collected from the water vapor may be increased.

In addition, by reducing the deflection flow of water vapor flowing through the plurality of dispersion members 160 to allow the water vapor to be dispersed and flow, the flow rate of the water vapor can be reduced, thereby increasing the amount of condensed water collected from the water vapor. You can.

In addition, the droplet growth unit 170 provides the time required for growth of the droplets generated from the water vapor contained in the fluid and at the same time uniforms the flow distribution of the fluid, thereby reducing the amount of condensed water collected from the water vapor contained in the fluid. You can increase it.

In the above description of the configuration and features of the present invention based on the embodiment according to the present invention, the present invention is not limited thereto, and various changes or modifications can be made within the spirit and scope of the present invention. As will be apparent to those skilled in the art, such changes or modifications fall within the scope of the appended claims.

1 is a block diagram showing a white smoke removal apparatus according to an embodiment of the present invention.

Figure 2 is a block diagram showing the internal configuration of the apparatus main body provided in the smoke removal apparatus according to an embodiment of the present invention.

3 is an operation diagram for explaining the operation of the smoke removal apparatus according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

100: smoke removal device 110: supply unit

120: device body 130: injection unit

140: first injection unit 150: second injection unit

160: dispersion member 170: droplet growth unit

180: adsorption unit 190: air supply unit

200: storage unit 210: heat exchange unit

Claims (13)

A supply unit for supplying a fluid containing water vapor; An apparatus unit connected to the supply unit and having an injection unit for injecting water for condensing the water vapor contained in the inflowing fluid by phase conversion; And And a heat exchange unit connected to the apparatus main body and supplying the outside air to the apparatus main body so as to be mixed with the fluid discharged from the apparatus main body after heat exchange with the condensed water condensed inside the apparatus main body and the sucked outside air. The apparatus body has a droplet growth unit disposed on the rear end of the injection unit on the flow path of the fluid and growing droplets generated from the water vapor contained in the fluid; And an adsorption unit provided at an upper end of the apparatus main body and adsorbing water vapor contained in the discharged fluid. The method of claim 1, The apparatus for removing white smoke further comprising a storage unit connected to the heat exchange unit to store the condensed water condensed by being phase-converted and condensed with water vapor contained in the fluid. . According to claim 1, wherein the heat exchange unit A heat exchanger for exchanging the sucked outside air with condensate supplied from the apparatus main body; An outside air inlet fan connected to the heat exchanger to introduce outside air; And A connection pipe connecting the heat exchanger and the device body to supply the outside air heat-exchanged with the condensate to the fluid discharged from the device body; White smoke removal device characterized in that it comprises a. According to claim 3, wherein the heat exchange unit And a replenishment water supply pipe connected to the injection unit such that the condensed water exchanged with the outside air is re-supplied to the injection unit. According to claim 1, wherein the injection unit A first injection unit having a first supply pipe through which water injected into the fluid is supplied, and a plurality of first injection nozzles installed in the first supply pipe to inject water into the fluid; And A second supply pipe for supplying water injected into the fluid, and a plurality of second injection nozzles installed in the second supply pipe for injecting water into the fluid, and spaced apart from the rear end of the first injection unit on the flow path of the fluid; A second injection unit; White smoke removal device characterized in that it comprises a. The method of claim 1, And a dispersing member provided in the apparatus main body so as to be disposed at the front end of the injection unit on the flow path of the fluid. The method of claim 6, wherein the dispersion member A first dispersing member disposed above the duct member to disperse the flowing fluid; And A second dispersing member disposed above the first dispersing member and dispersing the fluid so that the fluid passing through the first dispensing unit provided in the dispensing unit is dispersed and flows; White smoke removal device characterized in that it comprises a. delete The method of claim 5, And an external air supply unit provided in the apparatus main body so as to be disposed between the first and second injection units, and supplying external air to condense water vapor contained in the fluid. The air supply unit of claim 9, wherein the outside air supply unit is And a blower fan for sucking outside air into the device body, and an air supply pipe connecting the blower fan and the device body. delete The method of claim 1, wherein the adsorption unit And a first adsorption member for adsorbing the droplets contained in the fluid and grown, and a second adsorption member for adsorbing the droplets remaining in the fluid at a rear end of the first adsorption member on the flow path of the flowing fluid. White smoke removal device. The method of claim 1, wherein the supply unit And a flow path pipe through which water vapor flows, and a suction fan connected to the flow path pipe to introduce water vapor into the device body.

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